Author:
Nam Gi Baek,Ryu Jung-El,Eom Tae Hoon,Kim Seung Ju,Suh Jun Min,Lee Seungmin,Choi Sungkyun,Moon Cheon Woo,Park Seon Ju,Lee Soo Min,Kim Byungsoo,Park Sung Hyuk,Yang Jin Wook,Min Sangjin,Park Sohyeon,Cho Sung Hwan,Kim Hyuk Jin,Jun Sang Eon,Lee Tae Hyung,Kim Yeong Jae,Kim Jae Young,Hong Young Joon,Shim Jong-In,Byun Hyung-Gi,Park Yongjo,Park Inkyu,Ryu Sang-Wan,Jang Ho Won
Abstract
AbstractMicro-light-emitting diodes (μLEDs) have gained significant interest as an activation source for gas sensors owing to their advantages, including room temperature operation and low power consumption. However, despite these benefits, challenges still exist such as a limited range of detectable gases and slow response. In this study, we present a blue μLED-integrated light-activated gas sensor array based on SnO2 nanoparticles (NPs) that exhibit excellent sensitivity, tunable selectivity, and rapid detection with micro-watt level power consumption. The optimal power for μLED is observed at the highest gas response, supported by finite-difference time-domain simulation. Additionally, we first report the visible light-activated selective detection of reducing gases using noble metal-decorated SnO2 NPs. The noble metals induce catalytic interaction with reducing gases, clearly distinguishing NH3, H2, and C2H5OH. Real-time gas monitoring based on a fully hardware-implemented light-activated sensing array was demonstrated, opening up new avenues for advancements in light-activated electronic nose technologies.
Publisher
Springer Science and Business Media LLC